The depth of water affects wave size. As waves come toward land from the ocean, they are underwater. As the water (and wave) hit the bottom of the ocean approaching land, the wave is pushed up and becomes a very noticable event on the water surface. The more the water depth decreases, the farther the wave is pushed up - that's where those big surfer's waves come from.
When the size of the diffracting object is similar to the wavelength of the waves, diffraction effects become more pronounced. This occurs because the waves interfere with each other as they pass around the object, causing diffraction patterns to form. When the size is much smaller than the wavelength, diffraction effects are less noticeable.
Good effects of mechanical waves include communication through sound waves, medical imaging through ultrasound waves, and seismology for studying earthquakes.
The two factors that affect diffraction are the wavelength of the waves and the size of the obstacle or opening through which the waves pass. Smaller wavelengths and larger obstacles lead to more pronounced diffraction effects.
The size of the ball on the plunger does not affect the amplitude of the waves. The amplitude of the waves is determined by the energy put into creating the waves and the properties of the medium through which the waves travel. The size of the ball may affect other characteristics of the waves, such as frequency or wavelength, but not the amplitude.
A larger ball size on the plunger will generally result in greater displacement of the plunger when creating waves, leading to higher amplitude waves. Conversely, a smaller ball size will result in smaller displacements and lower amplitude waves.
When the size of the diffracting object is similar to the wavelength of the waves, diffraction effects become more pronounced. This occurs because the waves interfere with each other as they pass around the object, causing diffraction patterns to form. When the size is much smaller than the wavelength, diffraction effects are less noticeable.
Good effects of mechanical waves include communication through sound waves, medical imaging through ultrasound waves, and seismology for studying earthquakes.
The two factors that affect diffraction are the wavelength of the waves and the size of the obstacle or opening through which the waves pass. Smaller wavelengths and larger obstacles lead to more pronounced diffraction effects.
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waves
The size of the ball on the plunger does not affect the amplitude of the waves. The amplitude of the waves is determined by the energy put into creating the waves and the properties of the medium through which the waves travel. The size of the ball may affect other characteristics of the waves, such as frequency or wavelength, but not the amplitude.
Wind waves range in size from small ripples, to waves over 100 ft (30 m) high.[1]
Rogue waves can vary in size, but they are typically defined as waves that are substantially larger than the surrounding waves. They can reach heights of 80 feet (24 meters) or more, posing a significant threat to ships and offshore structures. Rogue waves are unpredictable and their exact size can vary depending on the conditions in which they form.
tidal waves and cgi effects
A larger ball size on the plunger will generally result in greater displacement of the plunger when creating waves, leading to higher amplitude waves. Conversely, a smaller ball size will result in smaller displacements and lower amplitude waves.
a wave that is about the size of a virus is ultraviolet a wave.
The force and speed of wind will determine how little and big the waves are.